Direct and Doppler angle-independent measurement of blood flow velocity in small-diameter vessels using ultrasound microbubbles

Homagni Sikha Roy; Guoqing Zuo; Zhengchun Luo; Hanping Wu; Tianyi M. Krupka; Haitao Ran; Pan Li; Youping Sun; Zhigang Wang; Yuanyi Zheng

doi:10.1016/j.clinimag.2012.01.026

Direct and Doppler angle-independent measurement of blood flow velocity in small-diameter vessels using ultrasound microbubbles

Homagni Sikha Roy, Guoqing Zuo, Zhengchun Luo, Hanping Wu, Tianyi M. Krupka, Haitao Ran, Pan Li, Youping Sun, Zhigang Wang, Yuanyi Zheng

Research output: Contribution to journal › Article › peer-review

12 Scopus citations

Abstract

This article represents an initial attempt to demonstrate the feasibility of a novel method for measuring flow velocity in small vessels, which is a direct, noninvasive, ultrasound-guided, and Doppler angle-independent method. In vitro, experiments were designed to mimic blood flow inside tubes. Harmonic ultrasound imaging was used to track the movement of microbubbles, and the mean flow velocity was calculated. In vivo, the flow velocities were measured in the central arteries of rabbit ears. This method can be used whenever the Doppler ultrasound cannot measure the velocity in small vessels because of either low sensitivity or Doppler angle limitation.

Original language	English (US)
Pages (from-to)	577-583
Number of pages	7
Journal	Clinical Imaging
Volume	36
Issue number	5
DOIs	https://doi.org/10.1016/j.clinimag.2012.01.026
State	Published - Sep 2012
Externally published	Yes

Keywords

Direct
Doppler angle independent
Small vessels
Ultrasound microbubbles
Velocity measurement

ASJC Scopus subject areas

Radiology Nuclear Medicine and imaging

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10.1016/j.clinimag.2012.01.026

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title = "Direct and Doppler angle-independent measurement of blood flow velocity in small-diameter vessels using ultrasound microbubbles",

abstract = "This article represents an initial attempt to demonstrate the feasibility of a novel method for measuring flow velocity in small vessels, which is a direct, noninvasive, ultrasound-guided, and Doppler angle-independent method. In vitro, experiments were designed to mimic blood flow inside tubes. Harmonic ultrasound imaging was used to track the movement of microbubbles, and the mean flow velocity was calculated. In vivo, the flow velocities were measured in the central arteries of rabbit ears. This method can be used whenever the Doppler ultrasound cannot measure the velocity in small vessels because of either low sensitivity or Doppler angle limitation.",

keywords = "Direct, Doppler angle independent, Small vessels, Ultrasound microbubbles, Velocity measurement",

author = "Roy, {Homagni Sikha} and Guoqing Zuo and Zhengchun Luo and Hanping Wu and Krupka, {Tianyi M.} and Haitao Ran and Pan Li and Youping Sun and Zhigang Wang and Yuanyi Zheng",

note = "Funding Information: This research is partially supported by National Natural Science Foundation of China ( No. 81130025, 30900371, 81110219 ), National Key Basic Research Program ( No. 2011CB707900 ), Foundation for Sci. & Tech. Research Project of Chongqing ( 2010AB50952 ), and Scientific Research Foundation for Returned Scholars ( No. 2010609 ). ",

year = "2012",

month = sep,

doi = "10.1016/j.clinimag.2012.01.026",

language = "English (US)",

volume = "36",

pages = "577--583",

journal = "Clinical Imaging",

issn = "0899-7071",

publisher = "Elsevier Inc.",

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TY - JOUR

T1 - Direct and Doppler angle-independent measurement of blood flow velocity in small-diameter vessels using ultrasound microbubbles

AU - Roy, Homagni Sikha

AU - Zuo, Guoqing

AU - Luo, Zhengchun

AU - Wu, Hanping

AU - Krupka, Tianyi M.

AU - Ran, Haitao

AU - Li, Pan

AU - Sun, Youping

AU - Wang, Zhigang

AU - Zheng, Yuanyi

N1 - Funding Information: This research is partially supported by National Natural Science Foundation of China ( No. 81130025, 30900371, 81110219 ), National Key Basic Research Program ( No. 2011CB707900 ), Foundation for Sci. & Tech. Research Project of Chongqing ( 2010AB50952 ), and Scientific Research Foundation for Returned Scholars ( No. 2010609 ).

PY - 2012/9

Y1 - 2012/9

N2 - This article represents an initial attempt to demonstrate the feasibility of a novel method for measuring flow velocity in small vessels, which is a direct, noninvasive, ultrasound-guided, and Doppler angle-independent method. In vitro, experiments were designed to mimic blood flow inside tubes. Harmonic ultrasound imaging was used to track the movement of microbubbles, and the mean flow velocity was calculated. In vivo, the flow velocities were measured in the central arteries of rabbit ears. This method can be used whenever the Doppler ultrasound cannot measure the velocity in small vessels because of either low sensitivity or Doppler angle limitation.

AB - This article represents an initial attempt to demonstrate the feasibility of a novel method for measuring flow velocity in small vessels, which is a direct, noninvasive, ultrasound-guided, and Doppler angle-independent method. In vitro, experiments were designed to mimic blood flow inside tubes. Harmonic ultrasound imaging was used to track the movement of microbubbles, and the mean flow velocity was calculated. In vivo, the flow velocities were measured in the central arteries of rabbit ears. This method can be used whenever the Doppler ultrasound cannot measure the velocity in small vessels because of either low sensitivity or Doppler angle limitation.

KW - Direct

KW - Doppler angle independent

KW - Small vessels

KW - Ultrasound microbubbles

KW - Velocity measurement

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JO - Clinical Imaging

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ER -

Direct and Doppler angle-independent measurement of blood flow velocity in small-diameter vessels using ultrasound microbubbles

Abstract

Keywords

ASJC Scopus subject areas

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